Decoding sequence information is equivalent to elucidating the design principles of proteins. For this purpose, we conducted systematic alanine insertion analysis to reveal the regions in the primary structure where the sequence continuity cannot be disrupted. We applied this method to dihydrofolate reductase (DHFR), and examined the effects of alanine insertion on structure and the enzymatic activity by solubility assay and trimethoprim resistance, respectively. We revealed that DHFR is composed of &ldquo;Structure Elements&rdquo;, &ldquo;Function Elements&rdquo; and linkers connecting these elements. The &ldquo;Elements&rdquo; are defined as regions where the alanine insertion caused DHFR to become unstructured or inactive. Some &ldquo;Structure Elements&rdquo; overlap with &ldquo;Function Elements&rdquo;, indicating that loss of structure leads to loss of function. However, other &ldquo;Structure Elements&rdquo; are not &ldquo;Function Elements&rdquo;, in that alanine insertion mutants of these regions exhibit substrate- or inhibitor-induced folding. There are also some &ldquo;Function Elements&rdquo; which are not &ldquo;Structure Elements&rdquo;; alanine insertion into these elements deforms the catalytic site topology without the loss of tertiary structure. We hypothesize that these elements are involved essential interactions for structure formation and functional expression. The &ldquo;Elements&rdquo; are closely related to the module structure of DHFR. An &ldquo;Element&rdquo; belongs to a single module, and a single module is composed of some number of &ldquo;Elements.&rdquo; We propose that properties of a module are determined by the &ldquo;Elements&rdquo; it contains. Systematic alanine insertion analysis is an effective and unique method for deriving the regions of a sequence that are essential for structure formation and functional expression.

f6-7_1: Mapping of the “Structure Elements” (a) and “Function Elements” (b) onto the structure of DHFR (PDB code: 1RX4). This figure was prepared using the program Weblab Viewer Pro18.

Mentions:
Based on these analyses, we propose that DHFR is composed of essential regions for structure formation, function expression and linkers connecting the elements. The “Structure Elements” and “Function Elements” are mapped onto the DHFR structure in Figure 6. These elements are the building blocks of protein architecture.

f6-7_1: Mapping of the “Structure Elements” (a) and “Function Elements” (b) onto the structure of DHFR (PDB code: 1RX4). This figure was prepared using the program Weblab Viewer Pro18.

Mentions:
Based on these analyses, we propose that DHFR is composed of essential regions for structure formation, function expression and linkers connecting the elements. The “Structure Elements” and “Function Elements” are mapped onto the DHFR structure in Figure 6. These elements are the building blocks of protein architecture.

Decoding sequence information is equivalent to elucidating the design principles of proteins. For this purpose, we conducted systematic alanine insertion analysis to reveal the regions in the primary structure where the sequence continuity cannot be disrupted. We applied this method to dihydrofolate reductase (DHFR), and examined the effects of alanine insertion on structure and the enzymatic activity by solubility assay and trimethoprim resistance, respectively. We revealed that DHFR is composed of &ldquo;Structure Elements&rdquo;, &ldquo;Function Elements&rdquo; and linkers connecting these elements. The &ldquo;Elements&rdquo; are defined as regions where the alanine insertion caused DHFR to become unstructured or inactive. Some &ldquo;Structure Elements&rdquo; overlap with &ldquo;Function Elements&rdquo;, indicating that loss of structure leads to loss of function. However, other &ldquo;Structure Elements&rdquo; are not &ldquo;Function Elements&rdquo;, in that alanine insertion mutants of these regions exhibit substrate- or inhibitor-induced folding. There are also some &ldquo;Function Elements&rdquo; which are not &ldquo;Structure Elements&rdquo;; alanine insertion into these elements deforms the catalytic site topology without the loss of tertiary structure. We hypothesize that these elements are involved essential interactions for structure formation and functional expression. The &ldquo;Elements&rdquo; are closely related to the module structure of DHFR. An &ldquo;Element&rdquo; belongs to a single module, and a single module is composed of some number of &ldquo;Elements.&rdquo; We propose that properties of a module are determined by the &ldquo;Elements&rdquo; it contains. Systematic alanine insertion analysis is an effective and unique method for deriving the regions of a sequence that are essential for structure formation and functional expression.